JP2018183562A - 3D scanner with accelerometer - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a 3D scanner.SOLUTION: The present invention relates to a 3D scanner comprising at least one scanning module (2, 7) for acquiring three-dimensional (3D) coordinates of a surface of an object (9) and a positioning device (1) on which the object (9) is placeable or fixable. The positioning device (1) is movable relative to the at least one scanning module (2, 7). The 3D scanner further comprises at least one accelerometer which is configured to measure a change of the position of the positioning device (1) relative to the scanning module (2, 7), and a first processing unit which is connected to the at least one scanning module (2, 7) and to the positioning device (1) for receiving data. The invention also relates to a method for scanning a surface of an object (9) to acquire three dimensional (3D) coordinates of the surface.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a 3D scanner comprising at least one scanning module for obtaining 3D coordinates of the surface of an object. The invention also relates to a method for scanning the surface of an object to obtain a three-dimensional (3D) coordinate of the surface.

  A three-dimensional scanner (3D scanner) for scanning the 3D surface of an object is widely used. A 3D scanner is a device that measures coordinates (X, Y, Z) for each point or many points on the surface of an object. EP3081980A1 discloses an optical scanning device and illumination device using a rotating shaft to rotate an anisotropic diffusing surface while a coherent light beam is demonstrated at the anisotropic diffusing surface. A method and system for obtaining 3D coordinates of the surface of an object by use of a laser is disclosed by US2016 / 169659A1. A laser scanner for measuring 3D coordinates from two positions including at least one accelerometer and a gyroscope is known from US 2016/245918 A1. Such a 3D scanner can only be used to scan objects at distance in the environment. Accurate measurement of the surface of the object is not possible, so such a scanner cannot be used to accurately scan the precise structure of the surface of the object. A 3D scanner with a stereoscopic illumination projector is known from US 2016/173855 A1. This 3D scanner can accurately measure the surface of an object with high accuracy and without contact by using spectral decomposition. Nevertheless, the setup is expensive and requires service for all parts to work, but complex surfaces cannot be easily measured by this setup.

  The result of such a measurement is that the depth (or distance) Z is generally expressed based on the position (X, Y) in the Cartesian coordinate system, so the so-called “depth” map of the surface as an image. Can be considered. The depth map so collected may then be used to build a three-dimensional composite image (digital object) for various purposes.

  A contact-free 3D scanner, for example, is a stereoscopic system based on the use of two cameras as a scanning module, where the cameras are slightly spaced and face the same scene, so that the depth is between the two images Inferred from geometric deformation.

  So-called “structured-light” 3D scanners are a specific family of contact-free 3D scanners. These scanners are configured by optical projectors that are typically manufactured on the principle of video projectors, or laser systems that produce interference fringes (so-called “phase shift” technology) and projectors for manufacturing stereoscopic configurations. It is constituted by at least one camera as a scanning module that is geometrically offset with respect to it. The projector projects a so-called “stereoscopic” pattern of light having one or two geometric dimensions, which can be colored on the surface for measurement. A camera positioned at a distance from a projector called "stereo basis" acquires and records an image of the scene. The projected three-dimensional pattern is constituted by appropriately selected basic patterns (also referred to as “three-dimensional elements”), and these can be detected in the acquired image.

  The disadvantages of these systems are primarily complex to use, in order to obtain coordinates when most of the scanned object is recorded in 3D, or when complex surfaces containing undercuts are scanned. That is, multiple scans from different angles are required. The object must be manually positioned, or the scanning module moves around the object, or the 3D scanner comprises a number of scanning modules that scan the object from different angles.

  The object of the present invention is therefore to eliminate the disadvantages of the prior art. In particular, a 3D scanner should be found that can scan a large portion of the surface of a relatively small object in detail, even if the surface is complex. The 3D scanner should be easy to use, simple to set up and as low as possible. The 3D scanner should also be able to be used flexibly and meet the individual demands of the user.

  An object of the present invention includes at least one scanning module for obtaining three-dimensional (3D) coordinates of a surface of an object, and a positioning device on which the object can be placed or fixed, and the positioning device includes the at least one scanning device. At least one accelerometer configured to measure a change in position of the positioning device relative to the scanning module; and the at least one scanning module And a first processing unit connected to the positioning device and receiving data, wherein one accelerometer of the at least one accelerometer is arranged in the positioning device or the at least one acceleration An accelerometer with a meter is arranged in the positioning device and has a different acceleration Is disposed in the scanning module, it is solved by the 3D scanner.

  Preferably, the at least one accelerometer is one accelerometer (meaning a single accelerometer). Particularly preferably, the accelerometer is arranged on a movable positioning device in order to detect movement of the positioning device relative to other fixed parts of the 3D scanner. Data is received by the first processing unit from the scanning module and the accelerometer. More preferably, the at least one accelerometer is at least one gyroscope sensor. The gyroscope sensor is not expensive and is easy to mount on the scanner according to the present invention. Furthermore, they communicate sufficient data to allow a good and accurate measurement of the position of a part of the sensor.

  The at least one accelerometer may be part of an inertial measurement unit (IMU). Nevertheless, preferably only one accelerometer is needed to keep the 3D scanner simple.

  According to the present invention, the positioning device is mounted on the scanning module so as to be rotatable around two different axes (X, Y), preferably around two orthogonal axes (X, Y). Or mounted rotatably about three different axes (X, Y, Z), preferably around three orthogonal axes (X, Y, Z), wherein the at least one accelerometer is relative to the scanning module It is preferably arranged to measure the rotation of the positioning device around these axes (X, Y) or (X, Y, Z).

  Thereby, the object can be scanned from different sides without moving the scanning module, and still scan the entire surface of the object and the vicinity of the complex surface structure of the object.

  One accelerometer of the at least one accelerometer is arranged in the positioning device or an accelerometer with at least one accelerometer is arranged in the positioning device and another accelerometer is arranged in the scanning module.

  This ensures that the relative movement between the scanning module and the positioning device is accurately measured. Thereby, the exact viewpoint of the scanning module can be determined and the coordinates of the surface of the object can be calculated from different scans.

  Further, it may be provided that the at least one accelerometer is configured to measure a change in the position of the positioning device along a defined and set degree of freedom.

  By using the degrees of freedom defined and set for relative movement, changes in the relative position of the positioning device relative to the scanning module can be easily and accurately determined.

  A further development of the invention is that the first processing unit or the second processing unit correlates 3D coordinates obtained from the scanning module with position data received from the at least one accelerometer, and By correlating 3D coordinates of different positions of the object with each other and / or superimposing the acquired 3D coordinates of the object at different positions and taking into account changes in the position of the object, It is also proposed to be configured to calculate combinations.

  Thus, the calculation of the total surface coordinates obtained can be widely automated and performed by the 3D scanner according to the present invention. A 3D scanner so constructed not only gives the opportunity to calculate 3D coordinates, but also explicitly calculates and presents the obtained 3D surface coordinates of the object.

  Such a 3D scanner according to the present invention further comprises a memory element in which correlated data is stored, wherein the first processing unit or the second processing unit is measured by the accelerometer. It is configured to calculate the entire surface of the object by matching the acquired coordinates of the surface of the object to changes in position data.

  This further completes the feasibility of calculating all the surface coordinates of the object by the 3D scanner.

  In another embodiment of the 3D scanner, the positioning device is shiftable along two different directions or three different directions with respect to the scanning module, the 3D scanner being linear as the at least one accelerometer An accelerometer and a gyroscope sensor, wherein the linear accelerometer is configured to measure a change in position of the positioning device caused by a transition of the positioning device with respect to the scanning module, the gyroscope sensor comprising: It is configured to measure a change in the angle of the positioning device caused by the position of the positioning device with respect to the scanning module. Preferably, the 3D scanner comprises an IMU that includes a gyroscope sensor and a linear accelerometer.

  Thereby, large or long objects can be scanned by the 3D scanner according to the present invention.

  In a further development of the invention, the 3D scanner is a 3D dental scanner, among artificial teeth, a series of artificial teeth, partial dentures, complete dentures, denture bases, dental impressions, and models of part of the patient's oral cavity. At least one of which is the object, which can be placed on or fixed to the positioning device.

  The 3D scanner according to the present invention is particularly useful for scanning teeth or artificial teeth so that it is compact and can also scan objects from various positions. A portion of the oral cavity is usually a part of the oral mucosa where a denture base is placed, or where a tooth covering or tooth bridge is placed, or where there is a remaining dentition in which a dental implant is inserted. It is a model.

  In a preferred 3D scanner, the positioning device is manually rotatable or rotatable and linearly movable with respect to the scanning module, or the positioning device has a preset degree of freedom for the scanning module. Can be rotated manually or can be rotated and moved linearly.

  This allows a fixed scanning module to be used while the object is manually moved to scan the object from different angles. 3D scanner operators often know the best that viewpoint is necessary or partly beneficial to quickly and effectively measure the relevant surface. Thus, a manually movable positioning device can be beneficial to benefit from the user's understanding. The scanning process is thereby easier and time saving.

  It is further proposed that the 3D scanner does not comprise a motor-like actuator for moving the positioning device relative to the scanning module.

  By not using an actuator such as a motor, a 3D scanner is inexpensive but suitable for scanning all accessible surfaces of an object. In addition, problems can occur during the scanning process, failure and need to be repaired.

  Further in accordance with the present invention, the 3D scanner further comprises a timer, and the first processing unit is adapted to measure a change in position measured by the at least one accelerometer or the IMU comprising the at least one accelerometer. By determining, it may be provided to be configured to determine whether there is a movement of the positioning device relative to the scanning module, or whether this movement exceeds a predetermined angular and / or linear velocity limit.

  This allows the 3D scanner to determine whether the scan to be performed is usable. Alternatively or additionally, scans while the object is moving can be computationally correlated to obtain more accurate results.

  In a preferred embodiment of the 3D scanner, the first processing unit is configured to start and stop the scanning process based on a determination of the movement of the positioning device and / or the 3D coordinates of the object are stored in memory. Is stored or not stored.

  This allows the 3D scanner to determine whether the scanning process can be started. Alternatively or additionally, scans while the object is moving can be computationally correlated to obtain more accurate results.

  According to certain preferred embodiments of the present invention, it may be provided that the scanning module is a stereoscopic illumination scanning module.

  The stereoscopic illumination scanning module operates by projecting a narrow band of light onto a three-dimensional shaped surface, producing illumination lines that appear distorted from other viewpoints that are not that of the projector. According to the present invention, it may be used to obtain an accurate geometric reconstruction of the surface shape of the object. A faster and more versatile method is the projection of a pattern consisting of many stripes or arbitrary stripes at once. This is because a large number of samples can be acquired simultaneously. From a different viewpoint, the pattern appears to be geometrically distorted due to the surface shape of the object. Many other variations of stereoscopic illumination projection are possible, but are considered within the scope of the present invention, and parallel stripes or grid patterns are preferably used in the present invention. Stripe or grid displacement allows for an accurate search of any detail 3D coordinates on the surface of the object.

  The positioning device is balanced in its weight distribution such that the center of gravity of the positioning device or the positioning device and the object system is at an intersection, and the intersection is at least around which the positioning device can rotate in parallel. It can also be provided that the two axes intersect or are around about 10% of the maximum diameter of the positioning device at the intersection.

  By this means, the positioning device can be rotated without torque acting on the positioning device or only with a low moment of torque when in the moving or rotating position. The rotated position of the positioning device is mechanically stabilized by this setting.

  According to another preferred embodiment of the present invention, the positioning device comprises a weight or a replaceable weight in which the center of gravity of the positioning device or the positioning device and the system of the object is moved to or near an intersection. At the intersection point, at least two axes intersect, and the positioning device can rotate around the intersection.

  By this means, the positioning device can be rotated without any torque acting on the positioning device or with only a low moment of torque, even when the object to be scanned is replaced. The rotated position is mechanically stabilized by this setting.

  Preferably, position data from at least one accelerometer is transferred to the first processing unit by wireless technology. Thus, the 3D scanner is connected to at least one accelerometer and transfers position data from the accelerometer to a wirelessly connected receiver and thereby to a first processing unit connected to the receiver. A module for wireless data transfer is provided. The receiver can be arranged on a motherboard having a first processing unit.

  The first processing unit is preferably a central processing unit.

  According to the invention, the positioning device can be realized as a spherical table carried in a support structure in which the spherical table can be rotated around three axes. The underside of the spherical table is realized by a spherical surface, in particular a hemisphere, which can be rotated relative to the center of the sphere. Of course, the spherical surface of the table is only a spherical region such as a spherical surface of a spherical segment or sector.

  According to a preferred embodiment of the invention, the positioning device is supported by a ball bearing or at least one ball caster. The ball bearing or at least one ball caster can be realized by the support structure or the positioning device itself.

The object of the present invention is also realized by a method of scanning the surface of an object to obtain three-dimensional (3D) coordinates of the surface, preferably using a 3D scanner according to the present invention,
A) the object is placed or fixed on the positioning device,
B) a first position of the positioning device is measured by at least one accelerometer;
C) The surface of the object is scanned by the scanning module;
D) The positioning device is rotated at least once relative to the scanning module to at least one second position, preferably by manual movement of the object or the positioning device;
E) the at least one second position is determined by the at least one accelerometer;
F) the surface of the object is scanned by the scanning module at each of the at least one second position;
G) a time series step in which 3D coordinate data of the surface of the object is obtained by correlating a scan of the surface at the at least two positions with the position determined by the at least one accelerometer.

  The at least one second position is different from the first position. Preferably, the correlated data is stored in memory.

  In the preferred method, the total 3D coordinate plane data of the object is calculated by overlaying the correlated coordinates of the surface scan at different positions.

  Thus, an easy method for calculating the total 3D coordinates obtained from the surface of the object is used.

  Preferably, the method is performed by a 3D sensor according to the present invention.

  The present invention determines the rotation of the positioning device by determining the position of the positioning device relative to the scanning module, which can be designed statically, where the scanned object is fixed or where the scanned object is located. Based on the surprising discovery that it is possible to scan the 3D coordinates of the surface of the object at different angles by using an accelerometer to thereby measure a large part of the surface of the object. A further advantage is that the scanning module does not have to be movable and can thereby be fixed to the stationary body of the 3D scanner. The present invention also makes it possible to build a manually movable positioning device by measuring changes in the position of the positioning device relative to other parts of the 3D scanner or relative to a stationary scanning module, which Allows the user of the scanner to determine that an object should be scanned at that angle. Thereby, a low-cost 3D scanner can be constructed. For small objects such as artificial teeth, partial dentures, complete dentures, dental impressions or models of part of the patient's oral cavity, according to the invention, only the positioning device can be rotated and scanned by at least one accelerometer. Preferably, the module only allows to measure different angular rotations around two or more axes of the object or positioning device, respectively. For this purpose, it is preferable to rotate at least one accelerometer as part of the positioning device. Even if the surface has a complicated shape such as an undercut or a hole, the 3D coordinates of the surface of the object can be measured.

  The 3D scanner and method according to the present invention has the advantage of reducing the complexity of the mechanical structure and the benefit of an additional third axis available for movement, which improves the scanning accuracy of the object. . This effect has a significant effect when the positioning device can be freely rotated in all directions even when some directions are limited. If the movement is driven manually instead of using motors and control electronics, the cost required to manufacture, drive and provide the 3D scanner is greatly reduced compared to a fully automated 3D scanner. The 3D scanner according to the invention is also optimized, allowing individually selected viewpoints for the scanning process and thus can be adapted to the external shape of the object to be scanned and / or the partial surface to be scanned. Enables a scanning process.

  According to a preferred embodiment of the present invention, a movable spherical table is used to realize a 3D positioning device according to the present invention. To be precise, the freely movable part of the sphere can be used to implement a positioning device. The movable or segmented spherical table for the positioning device in principle realizes a platform with an infinite number of stationary positions for six degrees of freedom, since the support structure supporting the spherical table is in all three directions. If it can be shifted, it is a rotation around the X-, Y- and Z- axes along transitions in the X-, Y- and Z- directions. When scanning the object, the software program accurately aligns the defined starting point and the resulting mesh data, and for each additional scan to calculate the 3D coordinates of the measured surface of the object. Requires each subsequent position.

  Since the position of the spherical table is infinite, and the movement of the spherical table requires a spherical geometry that is not blocked against the table in order to function correctly, it is conventionally mounted mechanically like a Hall effect sensor Sensors, some optical sensors and others cannot be mounted and used. The addition of an internal system to capture the position during the scan makes it possible to use a spherical shape for the scanning model movement to obtain the additional axis of rotation of the conventional two-axis movement. The position data (measured 3D coordinates of a single scan) is then acquired software that runs on the first processing unit for mesh data alignment by cable, WIFI, Bluetooth or other techniques. Passed to. The spherical table can be manually or automatically activated using a stepper motor or other similar technique.

  The final purpose of position measurement can alternatively be realized by two basic methods. First, mechanical: A specific sensor (encoder) is used for each degree of freedom of the movable table. Such an embodiment is mechanically complex. Second, optical: some special tags are added to the movable table. A scanning module, such as a stereo scanner camera, recognizes a tag for the table position, and a specific software computer calculates the table position. These tags need to be clean and need to be visible under any conditions by the scanning module. Scanned objects block the tags, and dust completely or partially hides them, preventing measurement. Thus, both methods have certain disadvantages that overcome the use of accelerometers according to the present invention.

  According to a preferred embodiment of the present invention, a series of integrated electronic circuit boards are mounted inside a spherical table and transmit the position in 3D space to the scanning computer via radio or cable. This data is used to accurately align the mesh data of the measured coordinates in subsequent scanning.

  Further embodiments of the present invention will be described with reference to the following five drawings, which do not limit the invention.

FIG. 1 shows a schematic plan view of a 3D scanner according to the present invention. FIG. 2 shows a schematic front view including a cross-sectional view of the main body of the 3D scanner according to FIG. FIG. 3 shows a schematic side view of the 3D scanner according to FIGS. 4 shows a schematic cross-sectional view through the positioning device for the 3D scanner of FIG. FIG. 5 shows a schematic cross-sectional view through the positioning device for the 3D scanner of FIG.

  1, 2 and 3 show a schematic plan view, front view and side view of a 3D scanner according to the invention. The 3D scanner includes a spherical table 1 that functions as a positioning device. The outline of the spherical table 1 is actually not entirely spherical, but is a hemisphere, which can be freely rotated with respect to the rest of the 3D scanner around three orthogonal axes. The maximum rotation angle is defined by the upper end of the spherical table 1 (upward in FIGS. 2 to 5, outside of the image plane in the direction of the viewer in FIG. 1). The table plate goes beyond the spherical surface, thereby preventing the spherical table 1 from being rotated around a maximum of 90 ° around two horizontal axes. The 3D scanner also includes two cameras capable of recording stereo images from the top of the spherical table 1. The main body 3 includes electronic components of a 3D scanner. The support arm 4 and the plate 5 from the main body 3 hold and position the camera 2. Preferably, the camera 2 and the support arm 4 and the plate 5 are firmly connected to the main body 3. Instead, the support arm 4 is also mounted on the body 3 so as to be linearly shiftable and / or rotatable and adapted to the scanning angle for scanning purposes.

  The spherical table 1 is carried by a support structure 22 (see FIGS. 2 and 3) that is firmly connected to the main body 3 via the support 6. The spherical table 1 can be rotated around three axes relative to the support structure 22. The projector 7 is connected to the support arm 4. The projector 7 irradiates the upper part of the spherical table 1 with stereoscopic illumination. The camera 2 and the projector 7 are firmly fixed to each other via the support arm 4 and the plate 5. The two cameras 2 and the projector 7 form the scanning modules 2 and 7 of the 3D scanner according to the present invention. It will be understood that when the projector 7 transmits stereoscopic illumination, the scanning modules 2 and 7 become stereoscopic illumination scanning modules 2 and 7.

  The strut 6 carries or supports the spherical table 1 with two further stands 8. The third stand 8 is fixed to the main body 3 of the 3D scanner. Thus, the entire 3D scanner can be stably placed or mounted on the three stands 8 on the surface. Slight unevenness can be flattened by adapting to the height of the legs of the stand 8. For this purpose, the legs are preferably connected to the arm of the stand 8 via threads and internal threads.

  The object 9 to be scanned is fixed to the spherical table 1 and illuminated by the three-dimensional illumination of the projector 7. The reflection of the stereoscopic illumination can be measured by a stereo camera 2 that forms a stereo image of the surface of the object 9. The fixing means (not shown) or the magnetic table 1 is moved to the spherical table 1 in order to avoid the movement of the object 9 relative to the spherical table 1 when moving the spherical table 1 relative to the scanning modules 2, 7 in the support structure 22. Used to fix the object 9.

  The graphic card 10 is used to evaluate the graphic signal from the camera 2 in order to generate 3D coordinates of the scanned surface of the object 9. The graphics card 10 includes a graphics chip for this purpose. The graphic card 10 is disposed inside the housing of the main body 3. In practice, the graphic card 10 can only be seen if the housing of the main body 3 is transparent in the area of the graphic card 10 as shown in FIG.

  The first switch 12 is disposed on the back side of the 3D scanner in order to switch the 3D scanner on and off. The second switch 14 is arranged in the projector 7 to tune the projector 7 or the scanning modules 2 and 7 and includes the projector 7 and the camera 2 and is turned on and off separately.

  The mirror 15 is disposed on the support arm 4, and is used for changing the optical path from the projector 7 in order for the camera 2 to illuminate the object 9 with stereoscopic illumination from a desired angle in the middle. Here, the projector 7 can be arranged at an actual position without causing illumination of the object 9 from an unfavorable angle with respect to the camera 2.

  FIG. 2 shows a schematic front view including a cross-sectional view of the body 3 of the 3D scanner. This makes it possible to see inside the main body 3 and all the electronic components present. Beside the graphic card 10, the main body includes a power source 16, a motherboard 18 and a hard disk 20 or a solid state disk 20 as electronic components. The mother board 18 has at least one central processing unit (CPU) and is programmed to carry out the method according to the invention, in other words, combining 3D coordinates from different positions and total 3D coordinates of the surface of the object 9 Is programmed to calculate the resulting set of

  FIG. 4 shows a schematic cross-sectional view through the positioning device 1 for a 3D scanner. The cut surface B is shown as a solid line B in FIG. FIG. 5 shows a schematic cross-sectional view through the positioning device for the 3D scanner of FIG. The cut surface A is shown as a solid line A in FIG.

  The spherical table 1 includes a weight 24 that moves the center of gravity of the spherical table 1 downward (downward in FIGS. 2 to 5 and to the image plane in FIG. 1). Thereby, the center position of the spherical table 1 shown and all other possible positions are stabilized. This central position is characterized by a plane parallel top surface on which the object 9 is placed or fixed at the ground level. In other words: the surface of the table 1 is aligned perpendicular to gravity. The weight 24 can be replaced by other weights and / or moved laterally to adapt the center of gravity to the different objects being scanned. For this purpose, the weight 24 is fixed to the spherical table 1 with screws 38. By exchanging the weight 24, it can be ensured that the center of gravity of the spherical table 1 with the object 9 remains in a place independent of the position of the spherical table 1. In other words: by adapting to the weight 24, the center of gravity of the system of the table 1 and the object 9 can be moved to the center of the sphere defined by the spherical surface of the spherical table 1, so that the spherical table rotates. In this case, a torque moment on the spherical table 1 can be avoided. Thereby, the center of gravity of the spherical table 1 or the system of the spherical table and the object 9 is moved to or near the intersection of three axes around which the spherical table 1 can rotate.

  Inside the spherical table 1, a gyroscope 26 as an accelerometer is mounted. The gyroscope 26 may be part of an inertial measurement unit (IMU) comprising at least one gyroscope sensor 26 and a linear accelerometer. The gyroscope sensor 26 can measure the rotation of the spherical table 1. Further, the power supply 28 and the WIFI module 30 are arranged inside the spherical table 1. The WIFI module 30 is connected to the gyroscope sensor 26 and can transmit the measured change of the position of the spherical table 1 to the CPU on the mother board 18 of the main body 3.

  The spherical table 1 has separate switches 32 by which the power of the table 1 can be turned on and off separately. The spherical table 1 is then carried by a support 34 having a hollow recess in which the spherical surface of the spherical table 1 can be freely rotated around three axes. The support 34 is carried by two of the stand 8 and the column 6. A support 34 for the spherical table 1 is fixed to the column 6 by two screws 36. The weight 24 is fixed to the inner surface of the spherical table 1 with a screw 38. At least one ball caster 40 for the spherical table 1 is mounted eccentrically to movably support the spherical table 1. The at least one ball caster 40 can also be used to measure and / or drive the rotation of the spherical table 1 inside the support structure 22 if the ball caster 40 can be driven by a motor (not shown). .

  The power supply 16 of the main body 3 supplies power to the projector 7, the camera 2 and the power supply 28 of the spherical table 1 together with all other electronic components and the support structure 22. The power supply of the spherical table 1 can be constructed independently of the power supply 16 in order to avoid the rotation limitation or disturbance of the movable spherical table 1. For this purpose, a battery or accumulator can be used as a power source. The motherboard 18 has at least one central processing unit (CPU), and the at least one CPU is indirectly connected to the graphic card 10 and the hard disk 20 or the solid state disk 20, and the camera of the spherical table 1, the projector 7 and the WIFI module 30. Connect to. The hard disk 20 or the solid state disk 20 can store all data temporarily and permanently. This data can be, for example, raw data from the camera 2 and processed 3D coordinates of the object calculated by the CPU from these raw data, by rotational alignment and IMU measured by the gyroscope sensor 26. Consider measured rotation and linear alignment. Therefore, the main body 3 can be regarded as a computer system of a 3D scanner.

  The measurement of the surface of the object 9 can be performed according to the following example: The object 9 is arranged or fixed on the upper flat surface of the spherical table 1. The positions of the object 9 and the spherical table 1 remain unchanged at the beginning and define the first position of the object 9. The starting position is measured by the gyroscope sensor 26 or the IMU that includes the gyroscope sensor 26, and the information is transferred by the WIFI module by sending data to the receiver (not shown), which is connected to the motherboard 18. Thereby, it is connected to the CPU on the mother board 18. The projector 7 illuminates the object 9 with stereoscopic illumination. The camera 2 receives reflected light from two different angles. The graphic card 10 calculates 3D coordinates of the proved surface of the object 9 at the first position of the spherical table 1. These 3D coordinates are stored in the hard disk 20 or the solid state disk 20 together with the position data.

  The position of the spherical table 1 is changed by turning, tilting or rotating the spherical table 1 and the object 9 thereon. The change in position is measured by the gyroscope sensor 26 or IMU. The change in position can be driven manually or by driving at least one ball caster 40 or by using a motor (not shown). As soon as the table 1 stops moving or is started with a manually or automatically generated signal, a second position of the spherical table 1 and the object 9 thereon is reached, the second position being determined by the gyroscope sensor 26 or Measured by the IMU and data is transferred by the WIFI module 30 as described above. At the second position, the surface of the object 9 is illuminated by the projector 7, the reflected light from the object 9 is recorded by the camera 2, and the surface coordinates of the object 9 at the second position are as described above. And stored in the hard disk 20 or the solid state disk 20 together with new position data. The measurement can be repeated for the table 1 and one or more additional positions of the object 9 as well.

  The CPU on the motherboard 18 combines the 3D coordinates stored on the hard disk 20 or the solid state disk 20 and considers different positions of the object, as in the case where the scanning modules 2 and 7 are moving around the object 9. To calculate a combined and final set of 3D coordinates of the surface of the object. The combined set of 3D coordinates is stored on the hard disk 20 or solid state disk 20 and / or transmitted to an external computer (not shown) for continuous use. Preferably, the combined set of 3D coordinates is stored and / or transmitted in a CAD format that can be used for a CAD-CAM-system.

  The features of the invention disclosed in the above detailed description, the claims, the drawings and the exemplary embodiments are essential both separately and in combination to implement the various embodiments of the invention. Can be.

DESCRIPTION OF SYMBOLS 1 Positioning device / spherical table 2 Camera / scanning module 3 Main body 4 Support arm 5 Plate 6 Post 7 Projector / scanning module 8 Stand 9 Object 10 Graphic card / electronic component 12 Switch 14 Switch 15 Mirror 16 Power supply 18 Motherboard 20 Hard disk / Solid state Disk 22 Support structure 24 Weight 26 Gyroscope sensor / accelerometer 28 Power supply module 30 WIFI module 32 Switch 34 Sensor support 36 Screw 38 Screw 40 Ball caster for positioning device

Claims (18)

A 3D scanner,
At least one scanning module (2, 7) for obtaining three-dimensional (3D) coordinates of the surface of the object (9);
A positioning device (1) on which the object (9) can be placed or fixed;
The positioning device (1) is movable relative to the at least one scanning module (2, 7);
The 3D scanner
At least one accelerometer (26) configured to measure a change in position of the positioning device (1) with respect to the at least one scanning module (2, 7);
A first processing unit connected to the at least one scanning module (2, 7) and the positioning device (1) for receiving data;
Further comprising
One accelerometer (26) of the at least one accelerometer (26) is arranged in the positioning device (1) or an accelerometer (26) with the at least one accelerometer (26) A 3D scanner arranged in the positioning device (1) and another accelerometer (26) arranged in the scanning module (27).   The positioning device (1) is mounted rotatably with respect to the scanning module (27) around two different axes (X, Y), preferably around two orthogonal axes (X, Y). Or mounted rotatably about three different axes (X, Y, Z), preferably around three orthogonal axes (X, Y, Z), the at least one accelerometer (26) being connected to the scanning module 2. The apparatus according to claim 1, wherein the rotation of the positioning device (1) around these axes (X, Y) or (X, Y, Z) is measured with respect to (27). The 3D scanner described.   The 3D scanner according to claim 1 or 2, wherein the at least one accelerometer (26) is at least one gyroscope sensor (26).   The at least one accelerometer (26) is configured to measure a change in the position of the positioning device (1) relative to the scanning module (27) along a defined and set degree of freedom. The 3D scanner according to any one of claims 1 to 3, wherein the 3D scanner is characterized by the following. The first processing unit or the second processing unit is:
Correlate 3D coordinates obtained from the scanning module (27) with position data received from the at least one accelerometer (26) and / or correlate 3D coordinates of different positions of the object (9) with each other And / or calculating the combination of 3D coordinates by superimposing the obtained 3D coordinates of the object (9) at different positions and taking into account changes in the position of the object (9),
The 3D scanner according to any one of claims 1 to 4, wherein the 3D scanner is configured as described above.   The 3D scanner further comprises a memory element (20) in which correlated data is stored, wherein the first processing unit or the second processing unit is the position data measured by the accelerometer (26). 6. The total surface of the object (9) is configured to be calculated by matching the acquired coordinates of the surface of the object (9) against changes in 3D scanner.   The positioning device (1) can be shifted along two different directions or three different directions with respect to the scanning module (2, 7), and the 3D scanner is connected to the scanning module (2, 7). A linear accelerometer configured to measure a change in position of the positioning device (1) caused by a transition of the positioning device (1), and the positioning device relative to the scanning module (2, 7) A gyroscope sensor (26) as one of the at least one accelerometer (26) configured to measure a change in angle of the positioning device (1) caused by the rotation of (1). The 3D scanner according to any one of claims 1 to 6, wherein   The 3D scanner is a 3D dental scanner, wherein at least one of artificial teeth, a series of artificial teeth, partial dentures, complete dentures, denture base, dental impression, and a model of a part of a patient's oral cavity is the object The 3D scanner according to any one of claims 1 to 7, characterized in that it is (9) and can be arranged or fixed to the positioning device (1).   The positioning device (1) is manually rotatable or rotatable and linearly movable with respect to the scanning module (2, 7), or the positioning device (1) is connected to the scanning module (2, 7). The 3D scanner according to any one of claims 1 to 8, wherein the 3D scanner is manually rotatable or rotatable and linearly movable along a degree of freedom set in advance to 7). .   10. The 3D scanner according to claim 1, wherein the 3D scanner does not include a motor-like actuator for moving the positioning device (1) relative to the scanning module (2, 7). The 3D scanner described.   The 3D scanner further comprises a timer, and the first processing unit determines a change in position measured by the at least one accelerometer (26) or an IMU comprising the at least one accelerometer (26). By means of this, it is arranged to determine if there is a movement of the positioning device (1) relative to the scanning module (2, 7) or if this movement exceeds a predetermined angular and / or linear speed limit The 3D scanner according to any one of claims 1 to 10, wherein:   The first processing unit is configured to start and stop the scanning process based on a determination of the movement of the positioning device (1) and / or the 3D coordinates of the object (9) are stored in a memory 12. The 3D scanner according to any one of claims 1 to 11, wherein the 3D scanner is configured to determine whether or not to be stored.   The 3D scanner according to any one of claims 1 to 12, wherein the scanning module (2, 7) is a stereoscopic illumination scanning module (2, 7).   The positioning device (1) is balanced in its weight distribution so that the center of gravity of the system of the positioning device (1) or the positioning device (1) and the object is at the intersection, and the intersection is positioned around the positioning 2. The device (1) according to claim 1, characterized in that at least two axes that can be rotated in parallel intersect or are around about 10% of the maximum diameter of the positioning device (1) at the point of intersection. The 3D scanner according to any one of 13.   The positioning device (1) includes a weight (24) or a replaceable weight (24) in which the center of gravity of the positioning device (1) or the positioning device (1) and the object system is moved to or near the intersection. 15. The 3D scanner according to any one of claims 1 to 14, characterized in that the intersection point includes at least two axes intersecting about which the positioning device (1) is rotatable. A method of scanning the surface of an object (9) to obtain three-dimensional (3D) coordinates of a surface,
The object (9) is arranged or fixed to the positioning device (1);
At least one accelerometer (26) measures the first position of the positioning device (1);
The surface of the object (9) is scanned by the scanning module (2, 7),
Preferably, the positioning device (1) is rotated at least once relative to the scanning module (2, 7) to at least one second position by manual movement of the object (9) or the positioning device (1). And
The at least one second position is determined by the at least one accelerometer (26);
The surface of the object (9) is scanned by the scanning module (2, 7) in each of the at least one second position;
3D coordinate data of the surface of the object (9) is obtained by correlating a scan of the surface at the at least two positions with the position determined by the at least one accelerometer (26);
A method comprising time series steps.   Method according to claim 16, characterized in that all 3D coordinate surface data of the object (9) are calculated by superimposing the correlated coordinates of the scan of the surface at different positions.   The method according to claim 16 or 17, wherein the method is performed by the 3D scanner according to any one of claims 1 to 15.

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